KR20090125252A - Method of frequency offset compensation - Google Patents

Abstract

The present invention provides a method of processing a baseband signal including user signals transmitted by a plurality of users. The method includes applying frequency offset compensations to the baseband signal, thereby to form respective frequency-shifted baseband signals. Each frequency compensation shifts the baseband signal by a multiple of a selected frequency offset and each resulting frequency-shifted baseband signal includes frequency-shifted user signals. The method also includes assigning at least some of the frequency-shifted user signals to groups. Each group corresponds to one of the frequency compensations and the assignment is carried out so that each group includes frequency-shifted user signals that have an estimated frequency offset that lies within a range determined by the corresponding frequency compensation. The method further includes estimating a frequency offset of each of the user signals based on the frequency-shifted user signal and the frequency compensation of the group including the frequency-shifted user signal.

Description

Frequency offset compensation method {METHOD OF FREQUENCY OFFSET COMPENSATION}

This application claims the priority of US Provisional Patent Application No. 60 / 918,825, filed March 19, 2007.

TECHNICAL FIELD The present invention relates generally to communication systems and, more particularly, to wireless communication systems.

Conventional wireless communication systems include a plurality of base stations or other devices for providing a wireless connection over an associated geographic area, commonly referred to as a cell. A mobile unit located in or near a cell associated with a base station may establish wireless communication links through an air interface between the mobile unit and the base station. . The nature of the air interface between the mobile unit and the base station is typically defined by industry-wide agreed standards and protocols. One exemplary set of standards and / or protocols is referred to as orthogonal frequency division multiple access (OFDMA). In an OFDMA system, an air interface is formed in a carrier frequency band that surrounds a plurality of sub-carrier frequency bands. Each sub-carrier is transmitted in a narrow frequency band centered on the sub-carrier frequency orthogonal to all other sub-carrier frequencies. Orthogonality of the sub-carrier frequencies allows multiple mobile units to establish simultaneous wireless communication links with each base station with minimal intercarrier interference. The use of multiple sub-carriers may also help to reduce multipath frequency selective fading of transmissions between the mobile unit and the base station.

1 conceptually illustrates a conventional processing flow 100 for extracting individual user signals from a multi-user super-positioned baseband signal. In the illustrated embodiment, a baseband signal comprising superposition of multiple user signals is received at the base station. After the cyclic prefix (CP) in the received symbols is removed (at 105) from the baseband signal, a fast Fourier transform is performed (at 110) to convert the baseband signal into the frequency domain. domain). Resource block demapping and demultiplexing is performed (at 115) to separate data traffic signals for each user, uplink control channel, and random access (RACH) channel. The RACH detection process is also performed on the baseband signal (at 120) and the information provided by the RACH detection process is used for downlink control.

2 conceptually illustrates a conventional processing flow 200 for performing RACH detection. In the illustrated embodiment, a long fast Fourier transform is performed (at 205) on the received baseband signal to transform the received signal into the frequency domain. The RACH signal is extracted (at 210) from the frequency domain signal. Discrete Fourier transform is performed at 215 with respect to the Zadoff-Chu criterion for the sequence corresponding to the expected RACH signal. The transformed Zadoff-Chu sequence is combined (at 220) with the extracted RACH signal and inverse discrete Fourier transform is performed (at 225) in accordance with the combined signals. The result of the inverse discrete Fourier transform of the combined signals can then be provided to a peak detection algorithm to extract the timing of the initial access signal from the unsynchronized RACH channel. A single FFT processor is commonly used for both data processing and RACH detection. This solution assumes that the multi-user superposition signals are perfectly time aligned, but this assumption is not always valid in practice.

Various factors can cause frequency mismatch between the sub-carrier frequency of the signal transmitted by the mobile unit and the signal received at the base station. For example, the Doppler shift caused by the relative movement of the mobile unit and the base station may induce a frequency offset between the sub-carrier frequency and the expected value of the sub-carrier frequency of the signal received at the base station. Can be. For another example, the oscillators used to generate the signal transmitted by the mobile unit and the inaccuracies in the oscillator used to generate the reference signal at the base station can induce a frequency offset. The frequency offset causes misalignment between the subcarrier center frequency and the fast Fourier transform kernels used to process the received signal. Moreover, the frequency offset is typically different for each unit. In conclusion, fast Fourier transform processing on a baseband signal operating on a received signal downconverted to baseband using a local reference oscillator convolves signals transmitted on different sub-carrier frequencies. (convolve) to cause interference between carriers.

3 conceptually illustrates subcarrier frequencies associated with two users. In the illustrated embodiment, each frequency band includes five subcarrier frequency bands 300, 305. Subcarrier frequency bands 300 associated with the first user are indicated by a solid line and subcarrier frequency bands 305 associated with the second user are indicated by a dotted line. Reference frequencies utilized by the receiver to perform the various Fourier transforms associated with the subcarrier frequency bands are indicated by bold arrows 310. The center frequency 315 of the first carrier frequency band is an offset from the reference frequencies 310 by a frequency offset Δf ₁ and the center frequency 320 of the second carrier frequency band is a reference frequency by a frequency offset Δf ₂ . Offset from fields 310. These frequency offsets for each user create a convolving effect in fast Fourier transform processing, which is inter-carrier interference between carrier / subcarrier frequency bands 300 and 305. Carrier interference occurs. Intercarrier interference is almost proportional to the degree of frequency offset.

Referring again to FIG. 1, intercarrier interference caused by convolution of signals in different subcarrier frequency bands occurs primarily at resource block 115 following fast Fourier transform processing 110. In conclusion, frequency offset estimation is typically performed using the extracted pilot symbols for each user after resource block demapping and user demultiplexing 115. For example, a multi-tap filter can be used to compensate for the converging effect of frequency offsets to reduce interference between carriers. Frequency offset compensation for each pilot and data subcarrier is performed before channel estimation and equalization, which is a very complex deconball (such as multi-tap filtering) to eliminate interference between carriers after FFT processing 110. Requires deconvolution operation Thus, when deconvolution operations are needed to compensate for the effects of frequency offset, conventional techniques for eliminating interference between carriers significantly increase the complexity of OFDMA baseband processing. Larger frequency offsets require increasing the number of taps to cover more subcarrier frequencies, thus increasing the complexity of the processing required to perform these operations. Moreover, a multitap filter should be applied to the signal associated with each user after fast Fourier transform processing 110.

The present invention is directed to solving the effects of one or more of the problems described above. The following provides a simplified overview of the invention to provide a basic understanding of some aspects of the invention. This summary is not an exhaustive overview of the invention. It is not intended to identify key or critical elements of the invention or to limit the scope of the invention. Its sole purpose is to present some concepts in a simplified form as a prelude to the more detailed description that is discussed below.

In one embodiment of the invention, a method is provided for processing a baseband signal comprising user signals transmitted by a plurality of users. The method includes applying frequency offset compensations to the baseband signal to form respective frequency-shifted baseband signals. Each frequency compensation shifts the baseband signal by a plurality of selected frequency offsets and each resulting frequency-shift baseband signal includes frequency-shifted user signals. The method also includes assigning at least some of the frequency-shift user signals to the groups. Each group corresponds to one of the frequency compensations and the assignment is performed such that each group includes frequency-shifted user signals with an estimated frequency offset that lies within the range determined by the corresponding frequency compensation. The method further includes estimating the frequency offset of each user signal based on the frequency-shift user signal and the frequency compensation of the group comprising the frequency-shift user signal.

The invention will be understood with reference to the following detailed description in conjunction with the accompanying drawings, wherein like reference numerals identify like elements.

1 conceptually illustrates a conventional processing flow for extracting individual user signals from a multi-user overlapping baseband signal;

2 conceptually illustrates a conventional processing flow for performing RACH detection;

3 conceptually illustrates subcarrier frequencies associated with two users;

4 conceptually illustrates one exemplary embodiment of a wireless communication system in accordance with the present invention;

FIG. 5 illustrates an example of block error rate (BLER) performance degradation due to interference between carriers for frequency offset errors;

6 illustrates BLER performance enhancement by single tap, three tap, and eleven tap convolution of frequency offset compensation;

7 conceptually illustrates one exemplary embodiment of a frequency offset estimation unit in accordance with the present invention;

8 conceptually illustrates one exemplary embodiment of a RACH peak detection element in accordance with the present invention;

Although various modifications and alternative forms of the present invention are possible, specific embodiments thereof are shown by way of example in the drawings and are described in detail herein. However, the description herein of particular embodiments is not intended to limit the invention to the particular forms disclosed, but on the contrary, all changes within the scope of the invention as defined by the appended claims, It is to be understood that the intention is to cover equivalents and alternatives.

Exemplary embodiments of the invention are described below. For clarity, not all features of an actual implementation are described in this specification. Of course, in the development of any such practical embodiment, it will be understood that numerous implementation-specific decisions should be made to achieve the specific goals of the developers, such as to meet system- and business-related constraints that may vary from implementation to implementation. . Moreover, while such development efforts can be complex and time consuming, it will nevertheless be understood that those skilled in the art will benefit from the disclosure herein.

Portions and corresponding detailed description of the invention are provided in symbolic representations of software, or algorithms, and operations on data bits in computer memory. These descriptions and representations are the ones by which those skilled in the art effectively convey the substance of their work to others skilled in the art. As used herein, and as generally used, an algorithm is considered to be a self-consistent sequence of steps leading to a desired result. The steps require physical manipulations of physical quantities. Typically, but not necessarily, these quantities take the form of optical, electrical, or magnetic signals that can be stored, transmitted, combined, compared, and otherwise manipulated. It has proven to be often convenient to refer to these signals as bits, values, elements, symbols, letters, terms, numbers, etc., primarily for common use reasons.

However, it should be borne in mind that both and similar terms will be associated with appropriate physical quantities and are merely labels given to these quantities for convenience. Unless stated otherwise or as apparent from the discussion, terms such as "processing" or "computing" or "calculation" or "judgment" or "displaying", etc., are referred to as physical and electronic quantities in a computer system's registers and memory. Action and processing of a computer system, or similar electronic computing device, that manipulates and converts the data into a computer system, or computer system memory or registers or other data similarly represented as a physical quantity within such information storage, transfer or display device. Refers to.

It should also be noted that software implementation aspects of the present invention are typically encoded in some form of program storage medium or implemented over some type of transmission medium. The program storage medium may be magnetic (eg, floppy disk or hard drive) or optical (eg, compact disc read only disk or CD ROM), and may be read only or random access. Similarly, the transmission medium may be twisted wire pairs, coaxial cable, optical fiber, or any other suitable transmission medium known in the art. The invention is not limited to these aspects of any given implementation.

The invention will be described below with reference to the accompanying drawings. Various structures, systems and devices are schematically depicted in the drawings for purposes of illustration only, so that the invention is not obscured by the details well known to those skilled in the art. Nevertheless, the attached drawings are included to describe and explain illustrative examples of the present invention. The words and phrases used herein are to be understood and interpreted to have a meaning consistent with the understanding of the words and phrases by those skilled in the art. The specific definitions of terms or phrases, that is, the definitions other than the usual and customary meanings understood by those skilled in the art, are not intended to be implied by the consistent use of the terms or phrases herein. To the extent that a term or phrase is intended to have a special meaning, ie, meaning different from what is understood by one of ordinary skill in the art, such particular definition is expressly described herein in a defined manner that directly and explicitly provides a particular definition for the term or phrase. Will be.

4 conceptually illustrates one example embodiment of a wireless communication system 400. In the illustrated embodiment, the wireless communication system 400 includes one or more base stations 405 for providing a wireless connection to an associated geographic area or cell. Base stations 405 provide wireless connectivity in accordance with multi-user single channel frequency division multiple access and / or orthogonal frequency division multiple access (SC-FDMA / OFDMA) standards and / or protocols. However, those skilled in the art having the benefit of the present disclosure will appreciate that the present invention is not limited to base stations 405 operating in accordance with the SC-FDMA / OFDMA standard and / or protocol. In alternative embodiments, other standards and / or protocols may be used to provide the wireless connection. Moreover, the present invention is not limited to using base stations 405 to provide a wireless connection. In alternative embodiments, an access network, access point, base station router, or other device may be used to provide the wireless connection.

Mobile units 410 (1 to 3) (which may also be referred to as users) access wireless communication system 400 by establishing wireless communication links 415 (1 to 3) with base stations 405. can do. Distinguishing indexes 1 to 3 may be omitted when collectively referring to mobile units 410 and / or wireless communication links 415. This convention may be applied to the other elements shown in the figures and may be referred to using an identification number and one or more distinct indices. The wireless communication link 415 operates according to SC-FDMA / OFDMA and thus supports channels within a range of frequencies located at the selected carrier frequency center. The channels are assigned to orthogonal subcarriers in the carrier frequency band. Establish, operate, and operate a wireless communication link 415 in accordance with SC-FDMA / OFDMA (or any other standard and / or set of protocols that use orthogonal carrier / subcarrier frequencies to define communication channels over an air interface), and Techniques for disassembling and / or are well known and for the sake of clarity only aspects of establishing, operating and / or disassembling a wireless communication link 415 related to the present invention will be discussed herein.

In ideal environments, for example, under perfectly fixed mobile units 410 transmitting at exactly specified carrier / subcarrier frequencies, the channels supported by the subcarriers are completely orthogonal. However, these ideal environments are virtually impossible to achieve (if any). In the illustrated embodiment, mobile units 410 move at the speed indicated by arrows 420. Rate 420 (1) is greater than rate 420 (2) and all of these speeds 420 (1-2) are directed away from the base stations 405, while rate 420 (3) is the base station. Headed directly to the field 405. In conclusion, the transmission over the air interface 415 is a Doppler shifted by a different amount, which causes the frequency of the signal received over the air interface 415 to be different from the transmission frequency of the signal. Both base stations 405 and mobile units 410 expect to transmit and receive signals at predetermined subcarrier frequencies, so Doppler shifting between the expected subcarrier frequency and the actual received subcarrier frequency. Induce frequency offsets. Moreover, environmental conditions and / or internal circuit differences of the mobile units 410 and / or base stations 405 may also result in frequency offsets.

Frequency offset can lead to performance degradation, which is mainly caused by interference between carriers. The degradation caused by the interference between carriers is a function of frequency offset error for each mobile unit 410. 5 shows an example of block error rate (BLER) performance degradation due to interference between carriers with respect to frequency offset error. Degradation rises to 2dB at BLER = 10 ^-2 when the frequency offset is 2000Hz, and the BLER degradation can be neglected below the frequency offset of 500Hz. 6 illustrates BLER performance improvement with single tap, three tap, and 11 tap convolution of frequency offset compensation. BLER performance is improved when longer taps are used. However, the complexity of the implementation also increases as the number of taps of the convolutional operation increases. 5 and 6 are sufficient for single tap frequency offset compensation to reduce BLER degradation to a negligible level for frequency offset in the ± 500 Hz range. However, one of ordinary skill in the art having benefit of the present disclosure will appreciate that this particular frequency offset range is exemplary and not intended to limit the present invention. Depending on the configuration of the elements of the wireless communication system 400, the range of frequency offsets that can be sufficiently compensated by single tap frequency offset compensation may vary from an exemplary range of ± 500 Hz.

In the illustrated embodiment, the base stations 405 include a frequency offset estimation unit 425. The multi-user data stream received via the air interface 415 is provided to the frequency offset estimation unit 425, which divides the data stream into a plurality of parallel data streams. Different frequency compensation is then applied to each of the plurality of parallel data streams. For example, a multi-user data stream can be divided into three parallel data streams and one of the parallel data streams can be processed without any frequency compensation. The other two parallel data streams can be shifted by a frequency of ± 1000 Hz. The frequency compensation applied to each of the parallel data streams can compensate for a portion of the frequency offset of the signals received from the mobile units. For example, after frequency compensation, the net frequency offset of signals received from mobile units 410 with a frequency offset of 1300 Hz is 1300 Hz without frequency compensation, 300 Hz with frequency compensation of 1000 Hz, and frequency compensation of -1300 Hz. Will be 2300 Hz.

As mentioned above, the complexity of frequency offset estimation can be significantly reduced when the expected frequency offset is within a limited range, for example ± 500 Hz. Thus, the frequency offset estimation unit 425 can form different parallel data streams with different frequency compensations. For example, if mobile unit 410 (2) has a previously determined frequency offset within ± 500 Hz, frequency offset estimation unit 425 may receive mobile unit 410 (2) from a parallel data stream that does not receive frequency compensation. You can select signals for. For another example, if mobile unit 410 (1) has a previously determined frequency offset of about -1300 Hz, frequency offset estimation unit 425 receives mobile unit 410 from the parallel data stream that has received a frequency compensation of -1000 Hz. We can select the signal for (1)), so the net frequency offset is expected to be about -300 Hz. As another example, if the mobile unit 410 (3) has a predetermined frequency offset of about 1300 Hz, the frequency offset estimation unit 425 receives the mobile unit 410 from the parallel data stream that has received a frequency compensation of 1000 Hz. The signal for 3) can be selected, so the net frequency offset is expected to be about 300 Hz.

If the frequency offsets are within the range of about ± 1500 Hz for all mobile units, then the frequency offset estimation unit 425 will select all mobile units 410 with a net frequency offset within a limited range that can be processed using a single tap filter. Signals can be shifted. In one embodiment, frequency offset estimation unit 425 may select a number of parallel data streams used to process the received signal. For example, if the frequency offset estimation unit 425 determines that the mobile units 410 have a very wide range of frequency offsets, additional parallel data streams with a wider range of frequency compensation may be used to process the received signal. May be included. Similarly, if mobile units 410 are expected to have a relatively small range of frequency offsets, frequency offset estimation unit 425 may reduce the number of parallel data streams. The frequency offset estimation unit 425 may also adjust the values of the frequency compensation based on information indicative of the expected range of frequency offsets for the parallel data streams, eg, the mobile units 410. In one embodiment, the number of FFT processors is dynamically determined by the number of frequency offset groups and the number of expected frequency offset ranges. For example, if the allowable frequency offset is ± 500 Hz before FFT processing, three FFT processors may be used to cover up to ± 1500 Hz of the frequency offset. The three FFT processors include one group for zero compensation, another group for +1000 Hz and another group for -1000 Hz frequency offset compensation. Alternatively, if most frequency offsets are within ± 500 Hz, one FFT processor will be needed as long as the frequency offsets are within ± 500 Hz.

The base stations 405 also include a random access channel (RACH) peak detection unit 430 used to estimate the peak at delay times associated with pilot signals received from the mobile units 410. The performance of peak detection unit 430 may be degraded by large frequency offsets generated by Doppler shifts of mobile units 410 with high mobility. Accordingly, the peak detection unit 430 may divide the received pilot signals into a plurality of parallel pilot signal data streams. Frequency compensation is performed on multiple parallel pilot signal data streams. In one embodiment, frequency offset compensation may be performed on parallel pilot signal data streams using the same function used to perform frequency offset compensation on multiple parallel data streams in frequency offset estimation unit 425. Peak detection can then be performed for the RACH preamble signals provided by the respective mobile units 410 in each parallel RACH preamble signal data streams and the strongest peak for each mobile unit 410 is the mobile unit. It is identified as the best estimate of the delay time associated with the fields 410.

The strongest peak may also correspond to the desired value of the frequency offset compensation for the corresponding mobile units 410. For example, three parallel pilot signal data streams may be formed and frequency offset compensations of 0 and ± 1000 Hz may be applied. If the strongest peak estimate in the delay time corresponds to a frequency compensation of 1000 Hz, this may indicate that the associated mobile units 410 have a frequency offset relatively close to 1000 Hz. This information can be used to select an appropriate data stream in frequency offset estimation unit 425.

7 conceptually illustrates one example embodiment of a frequency offset estimation unit 700. Those skilled in the art having the benefit of the present disclosure will appreciate that the frequency offset estimation unit 700 can be implemented in hardware, firmware, software, or any combination thereof, like the elements of unit 700. Moreover, various functional entities shown in FIG. 7 may be implemented as shown and may be combined with other devices or within devices. In the illustrated embodiment, the received baseband signal is divided into a plurality of parallel baseband data streams and each of the parallel baseband data streams is provided to a frequency offset element 705. Each frequency offset element 705 applies frequency compensation Δf ₁ , Δf _k to the data stream to form a frequency-shifted data stream. Each frequency offset compensation represents a different hypothesis regarding the range of frequency offsets associated with one or more user signals present in the received baseband signal.

Frequency offset storage and adjustment calculation element 710 may determine and / or provide a value for frequency compensation. In an embodiment, the device 710 may perform a function including selecting frequency offsets, selecting a number of frequency offsets, selecting a range of frequency offsets, and the like. For example, element 710 may determine the number of FFT processors to be used for the pre-set allowable performance degradation caused by each sub-frame and range of frequency offsets based on the frequency offsets of the scheduled users. Element 710 can receive information indicative of a predetermined frequency offset for different users and use this information to determine frequency compensation information.

Each frequency-shifted data stream is then provided to the CP cancellation element 715 to remove the CPs from the data stream and then provide the data stream to the fast Fourier transform (FFT) element 720. The fast Fourier transform element 720 converts the parallel baseband signals from the time domain into the frequency domain and then provides the frequency domain parallel baseband signals to the resource block demapping and multi-user demultiplexing element 725. Parallel baseband signals received at element 725 include signals corresponding to each user and each frequency compensation value. Thus, once the resource blocks in the parallel data streams provided by the fast Fourier transform element 720 are demapped and the multi-user signals are demultiplexed, the element 720 can select one of the frequency-shift user signals. Thus, the net frequency offset of the selected frequency-shift user signal is within a predetermined range. In one embodiment, device 720 utilizes predetermined frequency offsets provided by device 710 to select the appropriate frequency-shift user signal. For example, if a user's frequency offset is predetermined at 1200 Hz (either in pre-frequency offset estimation or as part of the RACH peak detection process), element 720 is associated with the user from the data stream from which the frequency offset compensation of 1000 Hz has been received. You can select the signals.

The selected frequency-shift user signals are then grouped by associated values of frequency compensation and provided to pilot symbol demodulation element 730 and frequency offset estimation element 735. In one embodiment, frequency offset estimation element 735 implements a single tap filter to estimate the net frequency offset for each of the users in the group. Once the net frequency offset is determined, the value of the frequency compensation can be combined with the net frequency offset to determine the frequency offset for each user. For example, if the net frequency offset for one user is 200 Hz and the user is part of a 1000 Hz frequency compensation group, then the frequency offset for this user is about 1200 Hz. The determined frequency offset may then be provided to device 710 for storage or for use in subsequent frequency compensation selection by using and / or selecting appropriate data streams within device 725.

8 conceptually illustrates one example embodiment of a RACH peak detection element 800. Those skilled in the art having the benefit of the present disclosure will appreciate that the RACH peak detection device 800 can be implemented in hardware, firmware, software, or any combination thereof, as with the devices of device 800. Moreover, various functional entities shown in FIG. 8 may be implemented as shown or may be integrated into other devices. In the illustrated embodiment, the received signal (including pilot signals transmitted by one or more users) is divided into a plurality of parallel pilot signal data streams, each of which is a frequency offset (FO) element ( 805. Each of the frequency offset elements 805 applies frequency offset compensation Δf ₁ , Δf _k to the data stream to form a frequency-shifted data stream. Each frequency compensation represents a different hypothesis related to the range of frequency offsets associated with one or more pilot signals present in the received signal. In one embodiment, the frequency offset elements 805 may be shared by frequency offset compensating elements, such as the frequency compensating element 700. However, this is not necessary for the practice of the present invention.

A long fast Fourier transform element 810 is used to convert each of the frequency-shift pilot signal data streams from the time domain to the frequency domain. RACH signal extraction is then performed at extraction element 815 and the pilot sequences are discrete Fourier transform of one or more reference sequences, such as Zadoff-Chu sequences, which may be provided by RACH signal and Discrete Fourier Transform (DFT) device 820. Is identified by combining. An inverse Discrete Fourier Transform (IDFT) element 825 is used to transform pilot signal sequences extracted back from the frequency domain to the time domain and then peak detection element 830 returns the peak value of the time delay for each user signal. Used to determine. Each user will have multiple peak values determined using different parallel preamble signal data streams and the strongest peak will be selected from these multiple peak values. Moreover, the selected peak will also correspond to the frequency offset or frequency compensation value. This value will then be used by the frequency compensating element, such as, for example, the frequency compensating element 700 shown in FIG. 7, as an estimate of the frequency offset for this user.

Embodiments of the techniques described herein may have a number of advantages over conventional implementations. The multiple FFT processing schemes described herein can allow time-domain frequency offset compensation for data and RACH processing over a wide range of frequencies using a significantly simpler structure. For example, the operations performed in the scheme described herein can be accomplished by single tap filters, which is considerably simpler than convolution operations using multiple tap filters required in conventional practice. Therefore, the proposed scheme limits the performance degradation caused by frequency offset to the acceptable range without the need to perform convolution operations for each user. The scheme proposed for RACH detection also improves detection performance for users with high mobility.

The particular embodiments described above are merely exemplary, and the invention may be modified and practiced in different but equivalent ways apparent to those skilled in the art having the benefit of the techniques herein. Moreover, no further limitation is intended to the details of construction or design herein shown, other than the claims set forth below. Accordingly, the specific embodiments described above may be changed and modified and it is obvious that all such changes are considered to be within the scope of the present invention. Accordingly, the scope of protection herein is set forth in the claims below.

Claims (9)

A method of processing a baseband signal including user signals transmitted by a plurality of users, the method comprising: Applying frequency offset compensations to the baseband signal to form respective frequency-shifted baseband signals, wherein each frequency compensation is applied to the base by a plurality of selected frequency offsets. Shifting a band signal and applying the frequency offset compensations, each resulting frequency-shift baseband signal comprising frequency-shift user signals; Assigning at least a portion of the frequency-shift user signals to groups, each group corresponding to one of the frequency compensations, wherein the allocation is estimated with each group within a range determined by the corresponding frequency compensation assigning at least some of the frequency-shifted user signals to groups, the frequency-shifted user signals being performed to include frequency-shifted user signals having an estimated frequency offset; And Estimating each frequency offset of the user signals based on the frequency-shifted user signal and the frequency compensation of the group including the frequency-shifted user signal. 2. The method of claim 1, comprising selecting the frequency compensations and the frequency offset. 3. The method of claim 2, wherein selecting the frequency compensations comprises selecting zero frequency compensation, wherein at least one positive frequency compensation has a magnitude that is an integer multiple of the selected frequency offset and at least one A negative frequency compensation has a magnitude of an integer multiple of the selected frequency offset. 3. The method of claim 2, wherein selecting the frequency compensations and the frequency offset is based on at least one of a predetermined frequency offset of a user signal and a preset allowable range of the frequency offset. And selecting an offset. 2. The method of claim 1, wherein assigning at least some of the frequency-shift user signals to groups comprises: assigning the frequency-shift user signals to one of the groups based on predetermined frequency offsets associated with each of the users. And assigning each one. 6. The method of claim 5, wherein assigning each of the frequency-shifted user signals to one of the groups comprises using a pilot signal after a Fast Fourier transform of the frequency-shifted baseband signal. The frequency-shift user in one of the groups based on at least one of a predetermined frequency offset using a determined frequency offset or a previous frequency-shift user signal and a frequency compensation of a group comprising the previous frequency-shift user signal. Assigning each of the signals. 2. The method of claim 1, wherein estimating frequency offsets for each of the users using the pilot signals provided by each of the plurality of users, wherein estimating the frequency offsets for each of the users corresponds to: Estimating the frequency offsets, including applying the frequency compensations to the pilot signal to form a plurality of frequency-shift pilot signals; And Determining a peak time for each of the frequency-shift pilot signals, wherein estimating the frequency offset for each of the users comprises the peak time for each of the frequency-shift pilot signals and the Determining the peak time, comprising combining the frequency compensation for each of the pilot signals. 2. The method of claim 1, wherein estimating the frequency offset of each of the user signals comprises a single tap on the frequency-shifted user signal to determine an associated frequency offset indicative of the frequency compensation related to frequency compensation of the corresponding group. A method of processing a baseband signal, comprising applying a single tap filter. 9. The baseband signal of claim 8, wherein estimating the frequency offset of each of the user signals comprises combining the associated frequency offset and the frequency compensation of the group containing the frequency-shifted user signal. How to handle it.

Images